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Research Article http://pubs.acs.org/journal/acscii

DNA’s Chiral Spine of Hydration M. Luke McDermott,† Heather Vanselous,† Steven A. Corcelli,‡ and Poul B. Petersen*,† †

Department of Chemistry and Chemical Biology, Cornell University, Ithaca, New York, United States Department of Chemistry and Biochemistry, University of Notre Dame, Notre Dame, Indiana, United States



S Supporting Information *

ABSTRACT: The iconic helical structure of DNA is stabilized by the solvation environment, where a change in the hydration state can lead to dramatic changes to the DNA structure. X-ray diffraction experiments at cryogenic temperatures have shown crystallographic water molecules in the minor groove of DNA, which has led to the notion of a spine of hydration of DNA. Here, chiral nonlinear vibrational spectroscopy of two DNA sequences shows that not only do such structural water molecules exist in solution at ambient conditions but that they form a chiral superstructure: a chiral spine of hydration. This is the first observation of a chiral water superstructure templated by a biomolecule. While the biological relevance of a chiral spine of hydration is unknown, the method provides a direct way to interrogate the properties of the hydration environment of DNA and water in biological settings without the use of labels.



INTRODUCTION The first few layers of water around DNA are critical to its structure and biological function. Dehydration can change the structure from the classic right-handed B-form to the shorter and wider A-form and the left-handed Z-form.1 Furthermore, interactions of DNA strands with small molecules and proteins are mediated by the solvation structure. As such, the hydrating water molecules form an activation barrier for molecular drugs targeting the major and minor grooves of DNA, and essential biological processes such as DNA transcription involving biomolecules binding to DNA displacing the solvation shell.2−5 Consequently, DNA’s hydration shell has been studied extensively with X-ray crystallography,6−9 neutron scattering,10 NMR spectroscopy,11−13 electronic14 and vibrational spectroscopy15 and molecular dynamics (MD) simulations.16,17 X-ray experiments performed at cryogenic temperatures have shown the existence of structural water molecules in particular minor groove sequences, giving notion to the presence of a spine of hydration in the DNA minor groove. NMR experiments have measured different time scales concerning the dynamics of water in the solvation structure of DNA,12,13 and time-resolved fluorescence measurements have suggested evidence of slow water molecules in the hydration shell,14 but the interpretation of the latter measurements has been questioned.16 Recent MD simulations have shown a broad range of water dynamics in the DNA solvation structure and identified very slow water molecules in the minor groove of DNA consistent with the structural waters observed in the X-ray experiments.17 To differentiate the bulk water response from the response of the relatively few hydration waters, many of the previous experimental methods have relied on cryogenic temperatures, indirect probes, dehydrated DNA, or other methods that likely disrupt the biologically relevant equilibrium hydration © XXXX American Chemical Society

structure. Recently third-order vibrational spectroscopy has been used to investigate the phosphate vibrations of DNA, indirectly probing the hydration structure.18 The present study focuses on directly targeting the solvation structure using second-order nonlinear vibrational spectroscopy, which is capable of probing interfacial and chiral structures in situ without relying on labels.19−21 The main idea is that if structural waters persist at room temperature, they should form an ordered, chiral, helical structure surrounding DNA. Using chiral sum-frequency generation (SFG) spectroscopy, we examine the vibrational frequencies of the hydration water molecules of two DNA sequences bound to a self-assembled monolayer under near-physiological conditions (room temperature and 100 mM NaCl solution). We indeed observe that DNA imprints its chirality on the surrounding water molecules, generating a chiral SFG water response. This confirms the existence of a DNA minor groove spine of hydration at room temperature and further shows that the chiral structure of biomolecules can be imprinted on the surrounding solvation structure.



APPROACH Chiral SFG has emerged as a powerful tool for studying chiral biomolecules.21−28 SFG is a nonlinear optical method in which an infrared and a visible photon interact with the sample producing a photon with the sum of the incident frequencies (energies). Second-order nonlinear optical techniques, like SFG, require a lack of inversion symmetry under the electric dipole approximation.19,20 Chiral-specific SFG spectroscopy is Received: March 6, 2017

A

DOI: 10.1021/acscentsci.7b00100 ACS Cent. Sci. XXXX, XXX, XXX−XXX

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Figure 1. Incident visible (green) and infrared (red) beams produce a second-order SFG signal (blue) at the buried surface-bound DNA/water interface. The inset shows click chemistry linking the DNA to a SiO2-coated CaF2 prism. The SFG beam’s polarization is rotated 45° by an achromatic waveplate (AW). The beam is then split into vertical and horizontal polarizations by a beam displacer (BD). Finally, the +45° and −45° polarized SFG responses are collected simultaneously (CCD). The difference between the measured +45° and −45° polarized SFG responses across the OH stretch region shown in the graph proves the existence of a chiral water superstructure surrounding DNA.

light fields linearly polarized at an odd angle, e.g., ±45°, containing both p and s polarizations. A chiral signature is then obtained by taking the difference between the +45° and −45° signals, analogously to circular dichroism.22,24,25,27,28 We have recently made technical advancements improving the sensitivity and reliability of chiral SFG spectroscopy.28 The chiral SFG method, illustrated in Figure 1, relies on simultaneously measuring two polarization components and rigorously calibrating the alignment through self-referencing. Here either the pure chiral and achiral SFG responses, or alternatively, the +45° and −45° polarized SFG responses, can be measured simultaneously. The blue and red arrows represent the orthogonally polarized achiral and chiral SFG signals, respectively, for a given set of incident polarizations. In the interference scheme, the orthogonal signals are first rotated by 45° by a waveplate. A beam displacer then splits the SFG signals into vertical and horizontal polarizations, containing the positively and negatively interfered achiral and chiral signals, which are then collected simultaneously. By measuring the +45° and −45° polarized SFG responses simultaneously, the difference signal is immune to laser fluctuations. Furthermore, the self-referencing approach described in the Supporting Information corrects for any potential false chiral responses from alignment imperfections. Both these improvements facilitate measuring the weak chiral imprint onto the solvation structure of DNA.

possible because chirality, by definition, breaks inversion symmetry. Where the chiral response in linear vibrational circular dichroism is on the order of 0.1%, the chiral SFG response can be on the same order of magnitude as the achiral SFG response.26 However, as a nonlinear optical method, chiral SFG typically suffers from a relatively poor signal-to-noise ratio, making it very difficult to detect a subtle chiral solvation structure. In linear spectroscopy, the small chiral response is separated from the large achiral response by taking the difference between two large signals containing both contributions, e.g., right- and left-handed polarized light. Similarly, chiral signatures can be detected in SFG spectroscopy by taking a difference between polarization combinations, but pure chiral signals can also be obtained. SFG spectroscopy involves three light fields that can be polarized either parallel (p) or perpendicular (s) to the plane of incidence, giving rise to eight distinct polarization combinations. Polarizations are listed in descending order of photon frequency, i.e., spp indicated spolarized SFG, p-polarized visible, and p-polarized IR beams. For a surface that is isotropic with respect to rotations within the plane (C∞), polarization combinations containing one or three p-polarized fields (ssp, sps, pss, and ppp) give rise to a signal for both chiral and achiral samples.21,26 However, polarization combinations containing two p-polarized fields (spp, psp, and pps) only produce a SFG signal for chiral samples. The polarization combination sss cannot produce a SFG signal. A full description of achiral and chiral SFG is given in the Supporting Information. Accordingly, pure chiral signals can be obtained in SFG spectroscopy, but given limitations to signal-to-noise, it is often advantageous to interfere a pure chiral with an achiral signal. This can be done by having any of the



RESULTS The results presented here are the first SFG experiments focused on the water OH stretch region surrounding DNA. Previous experiments examined the CH stretch region of B

DOI: 10.1021/acscentsci.7b00100 ACS Cent. Sci. XXXX, XXX, XXX−XXX

Research Article

ACS Central Science

Figure 2. Chiral SFG responses for 24-base pair double-stranded DNA sequences in aqueous 100 mM NaCl. (A) and (C) show results for 24 base pair double-stranded DNA consisting of alternating guanine and cytosine bases (GCGC). (B) and (D) show results for 24 base pair double-stranded DNA strands consisting of alternating thymine and adenine bases (ATAT). (A) and (B) demonstrate the chirality of the water around both sequences through the nonzero intensity of the pure chiral spp (red) and in the difference between the of the +45°pp (black), and −45°pp (green) spectra. (C) and (D) compare the normalized pure achiral ppp (gray), pure chiral spp (red), and interference +45°pp - −45°pp (blue) spectra. The interference chiral spectra have greater signal-to-noise ratios than the pure chiral results, but have similar spectral shapes. Compared to the achiral spectra, the pure and interference chiral spectra are red-shifted, indicating stronger hydrogen-bonded waters. In addition, a peak at 3660 cm−1 in (D) indicates non-hydrogen bonded chiral water population, attributed to non-hydrogen-bonded OH’s in contact with a hydrophobic surface in the ATAT minor groove.

surface bound DNA in contact with air using chiral SFG,25 showing that SFG is a sensitive probe of the structural chirality of DNA, and in contact with water using achiral SFG.29 The water OH stretch vibrational frequency probed here is very sensitive to the local hydrogen-bonded network with lower vibrational frequencies corresponding to stronger hydrogenbonded configurations.30 The OH stretch of the water−air surface spans the frequency range of 3000−3800 cm−1, but strongly hydrogen-bonded water can exhibit lower vibrational frequencies. Within the same frequency range, the NH stretch vibrations between DNA base pairs appear as two narrower features at 3200 and 3350 cm−1,15 but since these are orientated perpendicular to the DNA strain, they do not contribute to a net chiral superstructure. The strong difference between the +45°pp and −45°pp spectra shown in Figure 1 across the water OH stretch vibrational frequency region demonstrates the existence of a chiral water superstructure templated by the DNA helical structure. Chiral ordering of individual molecules in contact with small biomolecules has previously been observed in circular vibrational dichroism experiments on the water bend vibration and theoretical calculations.31−33 The present finding is the first discovery of a chiral water superstructure. Figure 2A,B compares the pure chiral spp SFG signal and the difference spectrum taken between the +45°pp and −45°pp polarized SFG responses for two DNA duplexes with 24 alternating GC or AT base pairs. Both sequences display a chiral water structure showing that the chiral structure is not sequence specific. The chiral signatures

measured by the two methods agree well, where the interference method exhibits improved signal strength. In addition to establishing the existence of a chiral water structure surrounding DNA at ambient conditions, our method facilitates characterizing the hydrogen-bonding strength of this chiral water superstructure. Figure 2C,D compares the achiral and interference chiral SFG response for the GCGC and ATAT duplexes. The achiral ppp spectra display a broad OH stretch band reflecting the broad range of hydrogen-bonding interactions in the solvation shell. The achiral signals contain three main features at 3200, 3400, and 3600 cm−1. While the 3200 and 3400 cm−1 features could result from inter- and intramolecular coupling between the OH vibrations as suggested for the air−water interface,34−37 for this complex system, they likely correspond to specific hydrogen-bonding interactions within the general solvation structure: the 3200 cm−1 band is due to water molecules orientated in the electric field from the DNA backbone charges, the 3400 cm−1 band is due to medium-strength hydrogen-bonded water molecules in the major and minor grooves, and the 3600 cm−1 band is due to weakly hydrogen-bonded water molecules in the grooves. The achiral SFG spectrum is consistent with the linear spectrum of DNA in weakly hydrated films.15 Compared to the achiral spectra, the interference chiral spectra for both the (GC)12 and (AT)12 duplexes are shifted to lower frequencies while still exhibiting a broad frequency distribution. This red shift reveals that the chiral water structure around DNA is more strongly hydrogen-bonded than the C

DOI: 10.1021/acscentsci.7b00100 ACS Cent. Sci. XXXX, XXX, XXX−XXX

Research Article

ACS Central Science general achiral solvation shell as expected due to the strong interaction of localized waters with the DNA base pairs. The chiral water structure around the (AT)12 duplex further displays a population of non-hydrogen-bonded OH stretch vibrations in contact with a hydrophobic structure at 3660 cm−1. Such nonhydrogen-bonded OH vibrations have previously been observed both at macroscopic flat hydrophobic surfaces,38,39 and in the solvation shell around hydrophobic residues.40−42 The observation of non-hydrogen-bonded OH vibrations in the solvation shell of DNA is initially surprising. However, it is known that the minor groove at AT base pairs is particularly narrow.43 An analysis of the sequence dependence of the minor groove width of 88 DNA crystal structures found that 82% of tetranucleotides with especially narrow minor groove widths (